INTRODUCTION: The posterolateral lumbar fusion (PLF) New Zealand White (NZW) (Oryctolagus cuniculus) rabbit model is a long-standing surgical technique for the preclinical evaluation of materials for spinal fusion. A detailed understanding of lumbar spine anatomy and perioperative care requirements of rabbits is imperative for correct execution of the model both scientifically and ethically. This study describes the preoperative procedures and surgical techniques used in single level PLF in a NZW rabbit model as it pertains to the animal husbandry, lumbar spine anatomy, anesthesia, surgical approach, and perioperative care of rabbits in a research setting. MATERIALS AND METHODS: We describe the surgical technique and perioperative patient care for single level PLF in a NZW rabbit model. Medical records from a single research facility were retrospectively reviewed for adult NZW rabbits that underwent single level PLF (L4-L5) between January 2016 and December 2019. The number of lumbar vertebrae per rabbit, fusion rates at 12 weeks using iliac crest autograft and complications are reported. Skeletal maturity was confirmed by preoperative fluoroscopic and radiographic documented closure of hindlimb physes. RESULTS: The PLF rabbit surgical model and perioperative patient care is described. PLF was performed in 868 adult female entire NZW rabbits. The majority of rabbits had seven lumbar vertebrae (620/868; 71.4%), followed by six (221/868; 25.5%), and eight (27/868; 3.1%). Fusion rates at 12 weeks for PLF using iliac crest autograft as assessed by manual palpation and radiographic assessment was 76.9% and 70.0%, respectively. Postoperative complications included occasional partial autograft site wound dehiscence due to self-trauma. CONCLUSIONS: For PLF rabbit models, a detailed understanding of the surgical technique, rabbit lumbar anatomy including number of lumbar vertebrae, and dietary and husbandry requirements of rabbits, is essential for execution of the model and animal welfare.
INTRODUCTION: The posterolateral lumbar fusion (PLF) New Zealand White (NZW) (Oryctolagus cuniculus) rabbit model is a long-standing surgical technique for the preclinical evaluation of materials for spinal fusion. A detailed understanding of lumbar spine anatomy and perioperative care requirements of rabbits is imperative for correct execution of the model both scientifically and ethically. This study describes the preoperative procedures and surgical techniques used in single level PLF in a NZW rabbit model as it pertains to the animal husbandry, lumbar spine anatomy, anesthesia, surgical approach, and perioperative care of rabbits in a research setting. MATERIALS AND METHODS: We describe the surgical technique and perioperative patient care for single level PLF in a NZW rabbit model. Medical records from a single research facility were retrospectively reviewed for adult NZW rabbits that underwent single level PLF (L4-L5) between January 2016 and December 2019. The number of lumbar vertebrae per rabbit, fusion rates at 12 weeks using iliac crest autograft and complications are reported. Skeletal maturity was confirmed by preoperative fluoroscopic and radiographic documented closure of hindlimb physes. RESULTS: The PLF rabbit surgical model and perioperative patient care is described. PLF was performed in 868 adult female entire NZW rabbits. The majority of rabbits had seven lumbar vertebrae (620/868; 71.4%), followed by six (221/868; 25.5%), and eight (27/868; 3.1%). Fusion rates at 12 weeks for PLF using iliac crest autograft as assessed by manual palpation and radiographic assessment was 76.9% and 70.0%, respectively. Postoperative complications included occasional partial autograft site wound dehiscence due to self-trauma. CONCLUSIONS: For PLF rabbit models, a detailed understanding of the surgical technique, rabbit lumbar anatomy including number of lumbar vertebrae, and dietary and husbandry requirements of rabbits, is essential for execution of the model and animal welfare.
Authors: Alexander M Riordan; Rajesh Rangarajan; Joshua W Balts; Wellington K Hsu; Paul A Anderson Journal: J Orthop Res Date: 2013-04-18 Impact factor: 3.494
Authors: Lukas A van Dijk; Davide Barbieri; Florence Barrère-de Groot; Huipin Yuan; Rema Oliver; Chris Christou; William R Walsh; Joost D de Bruijn Journal: J Biomed Mater Res B Appl Biomater Date: 2019-01-07 Impact factor: 3.368
Authors: Andrew L Alejo; Scott McDermott; Yusuf Khalil; Hope C Ball; Gabrielle T Robinson; Ernesto Solorzano; Amanda M Alejo; Jacob Douglas; Trinity K Samson; Jesse W Young; Fayez F Safadi Journal: J Orthop Sports Med Date: 2022-09-05
Authors: Ruggero Belluomo; Inazio Arriola-Alvarez; Nathan W Kucko; William R Walsh; Joost D de Bruijn; Rema A Oliver; Dan Wills; James Crowley; Tian Wang; Florence Barrère-de Groot Journal: Materials (Basel) Date: 2022-02-11 Impact factor: 3.623
Authors: Jacob T Landeck; William R Walsh; Rema A Oliver; Tian Wang; Mallory R Gordon; Edward Ahn; Colin D White Journal: J Orthop Surg Res Date: 2021-08-13 Impact factor: 2.359